Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
WO 91/06106 PCT/GB90/01594
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ELECTRICAL INSULATOR
DESCRIPTION
The present invention relates to an electrical insulator, and
in particular to an insulator formed from polymeric material.
Typically, insulators are formed from an elongate body of
electrically insulating material such as porcelain, with or without
the addition of an outer polymeric component, or from glass fibre
covered by a polymeric component. Metal fittings are mounted at
each end for connection to electrical equipment at elevated
voltage (typically greater, and often much greater than 1kV) and
(usually) earth respectively. The outer surface may be shedded
and/or convoluted, so as to prevent water flowing directly
between the end fittings and also so as to extend the creepage
path length.
In the case of a solid porcelain insulator, the sheds and/or
convolutions can be provided integrally with the porcelain core.
Alternatively, a cylindrical porcelain rod of uniform diameter may
have a polymeric component of shedded and/or convoluted
configuration mounted thereon. Due to the poor electrical and
water uptake properties of glass fibre, when an insulator core is
provided from such material an outer protective component is
necessary, and this can conveniently be provided by a shedded
and/or convoluted polymeric component.
Porcelain is a traditional insulator material, and is still
preferred in some applications because of its superior resistance
to damage by electrical discharges, to weathering, and to chemical
attack. However, it is relatively heavy, and is a brittle material
which can shatter on impact; in this respect, the convolutions or
sheds are particularly vulnerable. Furthermore, porcelain has a
high surface free energy, which makes it retentive to dirt. Its
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manufacturing process requires firing in a kiln, and this is not
conducive to the easy manufacture of complex shapes. It is.
however, not an expensive material to manufacture into an
insulator.
Polymeric insulators in general are suitable for many
applications, and are widely and successfully used, especially in
view of their low weight, particularly in relation to porcelain or
other ceramic materials, and their resistance to pollution, under
most severe conditions, for example at higher voltages and in
adverse operating conditions, particularly of heavy environmental
pollution. Furthermore, polymeric materials will usually maintain
their mechanical integrity if subjected to mechanical abuse, and
are relatively easy to form into complex shapes.
One example of a polymeric insulator is disclosed in British
Patent No. 1292276, and comprises a central support, which may
be a glass fibre rod or tube, having a metal fitting at each end and
an outer surface layer formed from a heat-shrinkable non-
tracking insulating polymeric sleeve that extends the entire length
of the support and overlaps each end fitting.
A further advantageous form of electrical insulator is
disclosed in EP-B-0125884, which comprises an insulator that is a
hybrid between a porcelain insulator and a polymeric insulator.
This insulator combines the advantages of the structural strength
of porcelain to form the insulator core, on the ends of which metal
connection fittings are mounted, with the advantages of lightness,
formability and mechanical (especially vandal) resistance of
polymeric material to form an outer component. The outer
component is spaced apart along the porcelain core from the metal
end fittings to avoid degradation of the polymer at such locations
due to intense local electrical activity.
However, porcelain and hybrid insulators still suffer from
the problems associated with the high density, and thus weight, of
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porcelain, and this disadvantage is also applicable to other
ceramics such as glass. Insulator cores of fibreglass on the
other hand are vulnerable to ingress of moisture which than,
due to the glass fibres extending continuously from one end of
the insulator to the other, wicks along the entire length of
the insulator, forming a conductive path and destroying its
operability. Furthermore, in applications involving
telecommunication links and particularly at high frequency,
any mechanical movement between the metal and fittings of the
insulator and the associated electrical equipment can give
rise to intermittent contacts that can generate electrical
noise.
Accordingly, it is one object of the present
invention to provide an electrical insulator that overcomes,
or at least alleviates, some or all of the above-mentioned
disadvantages.
In accordance with one aspect of the present
invention, there is provided an electrical insulator
comprising an outer component of generally tubular
configuration formed from electrically insulating,
substantially, non-tracking, polymeric material, and an inner
component formed from a substantially homogeneous, non-
hygroscopic, electrically insulating, polymeric material
having a Flexural Modulus lying within the range of about
0.5GPa to about 20GPa at 23°C.
Preferably the inner and outer components are
discrete, and the outer component is mounted on the inner
component.
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This aspect of the invention thus provides a two-
component insulator in which the inner component is of
polymeric material chosen for its mechanical properties such
that it is rigid enough to form a strength member and that is
water resistant, and in which the outer component is of
polymeric material chosen for its electrical properties in
providing a non-tracking and weather-resistance outer surface.
The material forming the inner component is such as not to
require the metal and fittings that are needed with known
insulators, since mechanical forces can be transferred to and
from the inner component directly by drilling and tapping
holes therein for example. Unlike an insulator having a
fibreglass core there are no continuous reinforcing filaments
that can be broken by such drilling, Which would otherwise
allow further opportunity for entry of water. Furthermore,
due to the inherent properties of the material, there is no
need to ensure, by means of conventional and fittings, that
the planar ands of the inner component are sealed against
moisture ingress.
For soma materials, it may be necessary, or
desirable, to add reinforcing filler material to produce the
required mechanical strength, and in such cases the filler may
comprise chopped fibrous material, which may be glass for
example. It will be understood that although the insulator of
the present invention may thus contain fibres of glass, these
are small in length, do not extend continuously from one end
of the insulator to the other, and thus do not destroy its
homogeneity, that is to say, there is no preferred orientation
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of the material of the inner component.
In general, the configuration of the insulator of
the invention will be elongate, with the inner component being
a cylindrical rod, and the outer component being mounted
thereon so as substantially to enclose, and thus electrically
protect, the entire outer surface of the inner component.
Depending upon how the connection is made between the
insulator and its associated electrical equipment, the,
usually planar, ends of the inner component may alternatively
be of hollow tubular configuration, provided that each end is
properly sealed so as to keep out Water or other moisture.
Advantageously, the material of the inner component
may be selecteda reaction injection moulded polyureal high
density
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polyethylene; polyethyleneterephthalate; VORYL, a polystyrene
modified polyphenyleneoxide available from General Electric
Corporation; polyetheretherketone; polybutyleneterephthalate:
polypropylene; polyethersulphone; and polyetherimide. The
material of the inner component advantageously has a dielectric
constant (petmittivity) no greater than about ~, which is
significantly less than the values (greater than 5) for porcelain,
glass or fibreglass. The inner component will thus have a
relatively small capacitance, which means that the amount of
radio noise generated is small. Such insulators are thus
particularly suitable for use with radio antennae.
The following materials, with the Flexural Modulus of a
corresponding rod (in GPa at 23° C) given in brackets, are
particularly suitable for use as the inner component of the
insulator of the present invention: polyetheretherketone (PEEK)
filled with 3090 by weight of chopped glass fibres ( 10); a
compound of unfilled polyethersulphone or polyetherimide (2.6);
polyethyleneterephthalate (PET) filled with 509'0 or 309b by weight
of chopped glass fibres ( 18.3, 11.3 respectively); unfilled PET
(2.5); polypropylene filled with 309'o by weight of chopped glass
fibres (6.0); unfilled polybutyleneterephthalate (PBT) (2.0); high
density polyethylene (HDPE) ( 1.0); and reaction injection moulded
(RIM) polyurea (0.5 - 0.1 ). Such materials are suitable for use in
the temperature range -40° C to +80° C, have a dielectric
strength
greater than lOkV/mm, have low water absorption, and maintain
good electric strength even when saturated with water.
For use outdoors and/or in contaminated environments, the
outer surface of the insulator advantageously has a shedded
and/or convoluted configuration. This can conveniently be
achieved by providing the outer component in the form of article
disclosed in GB-A-1530994, or GB-A-1530995, or EP-A-0147978, '
that is to say, a hollow article having an outer shedded and/or
convoluted configuration. Such articles are recoverable by the
application of heat thereto, but it is also envisaged that the outer '
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component may be applied without the application of heat
thereto, and may for example be an article of the kind disclosed in
EP-B-0210807.
Alternatively, the outer component may be moulded in
place on to the inner component.
Suitable heat recoverable articles for use as the outer
component of the insulator are available from Raychem under the
designation 200S Parts. These parts are both weather resistant,
i.e, have good resistance to ultra-violet radiation, ozone, salts and
water, and are also non-tracking, i.e. complywith the ASTM
D2303 inclined plane and IEC 112 comparative tracking index
specifications. Examples of suitable materials for the outer
component are disclosed in GB-A-1337951 and 1337952.
The entire disclosures of GB-A-1530994, GB-A-1530995,
EP-A-0147978, EP-B-0210807, GB-A-1337951 and 133?952 are
included herein by this reference.
In another embodiment of the invention, the inner
component, or strength member, can itself be formed in a shedded
and/or convoluted configuration, and the outer component can be
formed from a uniform tubular member. The uniform tubular
member is then mounted on the inner component so as
substantially to conform thereto. Advantageously, such
conformity can be achieved by forming the outer component from
a recoverable, for example heat-recoverable, tube of polymeric
material of substantially uniform diameter and wall thickness,
that is recovered on to the inner component. .
It is also envisaged that in accordance with the invention an
electrical insulator may be formed entirely from a homogeneous,
electrically insulating, substantially non-tracking non-hygroscopic
polymeric material that has a flexural modulus of at least about
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O.SGPa at 23° C. Thus the insulator may be formed from a single
component chat has the required mechanical and electrical
properties. It will be appreciated that such an insulator may be
formed from materials set out above or combinations thereof.
Insulators in accordance with the present invention will now
be described, by way of example, with reference to the
accompanying cross-sectional drawings.
Referring to Figure 1, the 250 mm long insulator, which is
suitable for use at 3kV, comprises an elongate cylindrical rod
forming an inner component 2 and a sheddcd tube forming an
outer component 4. The inner component 2 of diameter 20 mm
tapers slightly to a smaller diameter at each end, the taper
serving further to secure the outer component 4 which has been
recovered by heat into conformity with the inner component 2. A
hole 6 of diameter 10 mm is drilled and tapped through both
components at the reduced diameter ends to allow direct
attachment of the insulator to its associated electrical equipment. .
The outer component 4 has a series of larger diameter sheds 8
alternating along the length of the insulator with a series of
smaller diameter sheds 10, to give a total creepage distance of
650 mm.
Referring to Figure 2, the inner polymeric strength
component 20 of the insulator is itself formed from a solid body
having sheds 22 formed integrally therewith. The outer
component is provided by shrinking a hollow heat-shrinkable
tube 24 of uniform outer diameter over the core member 20 into
conformity therewith.
